Software architecture which maintains system performance while pipelining data to an MFP and uses shared DLL

ABSTRACT

A throttled data pipeline having a limited data-transfer rate for conserving system resources is disclosed. The throttled data pipeline of the present invention includes a source, a destination and a throttling device. The throttling device of the present invention is interposed between the source and the destination, and is adapted to limit data-transfer rates through the throttled data pipeline in accordance with predetermined criteria. By limiting data-transfer rates through the throttled data pipeline, system resources of the host computer, which would otherwise be wasted, are conserved. The throttled data pipeline of the present invention is configured to allow for fast and efficient transfers of data during low throughput operations when system resources are not significantly taxed. When high-throughput data transfers or other taxing operations which would otherwise detrimentally consume significant system resources are required of the throttled data pipeline, the data transfer rate of the throttled data pipeline is limited.

RELATED APPLICATION INFORMATION

This application is related to copending U.S. Application Number 09/016,190 entitled “Method of Administering a Work Group Fax Device,” which is commonly assigned and the contents of which are expressly incorporated herein by reference.

NOTICE OF COPYRIGHTS AND TRADE DRESS

A portion of the disclosure of this patent document contains material which is subject to copyright protection. This patent document may show and/or describe matter which is or may become trade dress of the owner. The copyright and trade dress owner has no objection to the facsimile reproduction by any one of the patent disclosure, as it appears in the Patent and Trademark Office patent files or records, but otherwise reserves all copyright and trade dress rights whatsoever.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates generally to image forming apparatuses and, more particularly, to methods and apparatuses for controlling a transfer rate of image data within the image forming apparatuses.

2. Description of Related Art

As new computer systems and applications are developed and introduced into the marketplace, a primary motivating element in the evolution of economical and effective products continues to be increased processing speed. Regardless of the particular task at hand, few would disagree that, other things being equal, the quicker product will usually claim the market share.

In a typical networked multi-user computer environment, a number of individual workstations are linked together through a high speed network, usually a local area network (LAN). Also linked on the LAN are one or more peripheral devices such as printers, facsimile machines, scanners or plotters. One or more file servers are also linked to the network and serve to manage allocation of the devices to workstations which request the use of the devices. The allocation procedures typically involve accepting requests, determining the address of the device requested, maintaining queues, establishing priorities and relaying data from the workstation to the device.

Typically when a workstation user wishes to determine the status of a device that is networked on a LAN, the method available depends upon the intelligence of the device. The earlier generation of peripherals were “unintelligent,” or perhaps, better “uncommunicative.” They accepted data from the LAN and processed it according to instructions, but were incapable of relaying status information back to the LAN. A workstation user, concerned about the status of a device to which he or she had sent a job, would have to leave the workstation to physically examine the device.

A server, such as a file server or a print server, might be able to provide some information regarding the status of a print job. However, this status information related to the status of the print job in a print queue, and the print queue was neither created, maintained nor serviced by the printer. If a print job was removed from the print queue, one could infer that the printer was handling the print job. However, the status of the print job as it was handled by the printer could not be ascertained. For example, absence of a print job from the print queue could mean that the print job was complete, or it could also mean that the printer had received the print job into its buffer and was still processing the print job. Other features of such a print queue manager were reprioritization of print jobs and deletion of print jobs.

More recently, peripheral devices have become available which are able to perform a number of related functions. These devices are known as multifunction peripherals (MFPs).

The Telecommunication Industry Association (TIA) has provided an MFP interface standard known as the IS-650 Multifunction Peripheral Industry Interface Standard, Level 1 (MFPI-1) specification version 5.5. According to this standard, an MFP is:

Computer equipment used to scan, print, facsimile transmit, and/or copy documents. It also may have the capability to provide data modem and other voice telephony services. The MFP may be an integrated unit or may be several discrete units that are interconnected on the same communication channel to the Host or interconnected using several different channels. One or more of the subsystems may be omitted from the MFP.

A “Host” as defined in MFPI-1 is any terminal or computer capable of providing commands and data to operate a peripheral, and in practice is a computer of any size, or a group of network nodes on a given local area network. As used herein, a “host” is a generic Host, providing the quality of functionality specified in MFPI-1 without necessarily adhering to the specification. A “subsystem” according to MFPI-1 is one of several logical peripheral units, such as printer, scanner, fax-data-voice (FDV) modem, internal memory, stand-alone controller (SAC), operator console and others which may exist in the MFP or Host. The Host and the MFP communicate through a “channel.”

An MFP can operate in stand-alone mode, wherein two or more subsystems are used without interaction with the Host. One example of this is copying. Stand-alone operations may occur at the same time that the Host is accessing a different subsystem for a Host-controlled operation.

In a networked system where many workstations are sharing peripherals, the use of a multifunction peripheral is a mixed blessing. On the one hand, rather than providing, for example, two different scanner functions (one for reading documents for facsimile transmission, one for reading documents for copying) and three different printing functions (one for printing computer generated documents, one for printing documents received through facsimile transmission, and one for printing documents that have been scanned in for copying), a single scanning function and a single printing function perform the work of printer, copier and facsimile machine. On the other hand, the single multifunction peripheral is used at least as often as all of the individual devices would have been used alone. Previously, where there was one user wishing to print a document, one user wishing to transmit a document via facsimile, and one user wishing to copy a document, each would ordinarily each have directed his or her task to a separate machine, and thus not interfere with one another. If any one of these devices was busy or overloaded, the others could perform unimpeded. With a single machine performing all three functions (in our example), reliable processing speeds are more important to ensuring the productivity enhancing capabilities and cost savings of the MFPs. Having many processes operating in the MFP at any given time can severely tax or overload the system resources of the MFP.

MFPs have generally been somewhat simple as to programmability and functionality. A conventional MFP may be confined to DOS-based controllers or dedicated/specific purpose boards. There has been little, if any recognition of the problem of processing throughput.

SUMMARY OF THE INVENTION

The previously described problems are solved in a software architecture which maintains system performance while pipelining data in an image processing system. System resources of a host are efficiently apportioned by a data storage and retrieval unit (DSRU) between a image data processing processes in the host. The image data processing processes involves a transfer of image data from a respective originator service to a respective recipient service.

In accordance with the method, the DSRU identifies an available number of face buffers based upon available system resources. After one of the services requests a face buffer from the DSRU, the DSRU identifies an available number of face buffers which meet the requested criteria. If at least one face buffer of the requested type is available, then the DSRU returns a location of the one available face buffer to the requesting service. If the DSRU is unable to identify any face buffers of the requested type, then the DSRU delays until at least one face buffer of the requested type becomes available.

Still further objects and advantages attaching to the device and to its use and operation will be apparent to those skilled in the art from the following particular description.

DESCRIPTION OF THE DRAWINGS

Further objects of this invention, together with additional features contributing thereto and advantages accruing therefrom, will be apparent from the following description of a preferred embodiment of the present invention which is shown in the accompanying drawings with like reference numerals indicating corresponding parts throughout and which is to be read in conjunction with the following drawings, wherein:

FIG. 1 is a block diagram of a LAN including a plurality of multifunction peripherals.

FIG. 2 is a block diagram of a data processing system including a Host and an MFP.

FIG. 3 is a block diagram illustrating a flow of data within a print system in accordance with the invention.

FIG. 4 is a block diagram illustrating a flow of data within a facsimile send system in accordance with the invention.

FIG. 5 is a block diagram illustrating a flow of data through a DSRU in accordance with the invention.

FIG. 6 is a flow chart of a method of using the DSRU of FIG. 5 to throttle a flow of data through both the print system of FIG. 3 and the facsimile send system of FIG. 4 in accordance with the invention.

FIG. 7 is a first exemplary timing diagram illustrating a sequence of communications among the DSRU, the print system and the facsimile send system, in accordance with the invention.

FIG. 8 is a second exemplary timing diagram illustrating a sequence of communications among the DSRU, the print system and the facsimile send system, in accordance with the invention.

These and additional embodiments of the invention may now be better understood by turning to the following detailed description wherein an illustrated embodiment is described.

DETAILED DESCRIPTION OF THE INVENTION

Throughout this description, the preferred embodiment and examples shown should be considered as exemplars, rather than limitations on the apparatus and methods of the present invention.

Referring now to FIG. 1 there is shown a block diagram of a local area network (LAN) 100 in accordance with the present invention. The LAN 100 includes a file server 120, printer 130, workstations 150, and a Host 110 b coupled to one another via network communications lines 160. The file server 120 and workstations 150 are preferably those well known in the art, such as computers having Intel Corporation (Santa Clara, Calif.) microprocessors and running Microsoft Corporation (Redmond, Washington) Windows or Windows NT operating systems. A multifunction peripheral (MFP) 110 a is coupled to the Host 110 b. The LAN 100 may also include hubs, routers and other devices (not shown).

Before proceeding to describe the LAN 100, a few terms are defined. By “file server,” it is meant a computer which controls access to file and disk resources on a network, and provides security and synchronization on the network through a network operating system. By “server,” it is meant hardware or software which provides services to other hardware or software. By “workstation,” it is meant a client computer which routes commands either to its local operating system or to a network interface adapter for processing and transmission on the network. A workstation may function as a server by including appropriate software, and may be for example, a print server, archive server or communication server. By “software” it is meant one or more computer interpretable programs and modules related and preferably integrated for performing a desired function. A “multifunction peripheral” is a peripheral which provides the functions of more than one peripheral, typically providing printing and at least one of: copying, scanning and faxing.

Turning now to FIG. 2, there is shown a block diagram of a data processing system comprising the MFP 110 a and the Host 110 b. The MFP 110 a preferably comprises a high output digital copier having a communications interface 220, which as presently embodied comprises a small computer systems interface (SCSI). The MFP 110 a further preferably comprises a hardware and software interface which allows the MFP 110 a to receive rasterized print jobs from the Host 110 b, manage the print jobs as well as its own copy jobs, and print the print jobs. The hardware and software interface of the MFP 110 a further allows the MFP 110 a to forward facsimile send jobs from the MFP 110 a to a fax/modem 210 in the Host 110 b. The MFP 110 a includes a short term memory 265, which preferably comprises random access memory (RAM) and a processor 260 in which programs are stored and run, respectively, for controlling the functions of the MFP 110 a. The MFP 110 a preferably also includes a long term memory 285 such as a read only memory (ROM) or electronically programmable read only memory (EPROM). The MFP 110 a may also include a disk drive (not shown) for both long term and short term storage. The MFP 110 a includes standard components including an automatic document feeder 275, paper bin 270 and paper output tray 235.

The MFP 110 a includes a non-fixed display 225, preferably a liquid crystal display (LCD), and a user input device 230, such as button switches. The MFP 110 a has user interface software stored in the memory 285 which is responsible for displaying information on the display 225 and interpreting user inputs from the user input device 230. The nonfixed display 225 and user input device 230 comprise an operator console 240, which, together with the user interface software, comprise a panel subsystem.

The Host 110 b preferably comprises a server, and is a computer having an Intel processor 255 and running Microsoft Windows NT. To maximize efficiency, there is preferably a one-to-one correspondence between Hosts and MFPs. In conjunction with the processor 255, the Host 110 b has a short term memory 250 (preferably RAM) and a long term memory 280 (preferably a hard disk) as known in the art. A fax/modem 210 is for sending and receiving facsimiles via telephone lines. The Host 110 b preferably provides storage, for example in long term memory 250, for holding incoming facsimile transmissions for extended periods and in substantial amounts when a hold is placed on printing facsimile jobs. The Host 110 b includes a communications interface 205 through which the Host 110 b communicates with the MFP 110 a via a channel 290. Preferably, the communications interface 205 is configured as a SCSI Host.

The Host 110 b further preferably comprises a hardware 215 and software interface which allows the Host 110 b to receive print jobs and facsimile send jobs from the LAN 100, receive facsimile jobs from the MFP 110 a and transmit rasterized print jobs to the MFP 110 b. The Host 110 b includes management software stored in the long term memory 280 for managing print jobs, facsimile jobs and scan jobs. The Host 110 b rasterizes print jobs received from the LAN 100 into print data (in a form native to the MFP 110 a) and transmits the print data to the MFP 110 a via the communications interface 205. The Host 110 b executes facsimile send jobs, received from either the LAN 100 or the MFP 110 a, on the fax/modem 210.

FIGS. 3 and 4 are block diagrams illustrating data flow in accordance with the invention between several functional units of the Host 110 b. In both figures the functional units include applications, host subsystems and transports, and are conceptually organized into applications layers 310, 410, subsystems layers 320, 420 and transports layers 330, 430. As presently embodied, applications are purely software which run on the Host 110 b. Host subsystems comprise software for interfacing to I/O devices such as the MFP 110 a, the fax/modem 210 and the communications interface 205. Transports comprise software interfaces between higher level functional units, typically host subsystems, and the I/O devices themselves. Applications and host subsystems are services of the Host 110 b.

In FIG. 3, a print application 313 is shown in the applications layer 310. In FIG. 4, a facsimile send application 411 is shown in the applications layer 410. Other applications, such as a facsimile receive application and/or a scan application could be included in the applications layer. All of these applications have access to the host subsystems and transports as necessary to carry out their functions. For example, the print application 313 administers the printing of print jobs received by the Host 110 b from the workstations 150.

The print application 313 is responsive to control messages sent by the workstations 150 for controlling how print jobs received from the workstations 150 are processed. In an alternative embodiment, the print application 313 is also responsive to control messages sent by the MFP 110 a for controlling how print jobs received from the workstations 150 are processed. The print application 313, in response to the control messages, can then act upon and respond differently to other functional units. Also included in the applications layer 310 are a page description language (PDL) interpreter 311 and a data storage and retrieval unit (DSRU) 315.

The host subsystems of FIG. 3 include a printer subsystem 321 and a network management subsystem 325. The printer subsystem 321 comprises software which manipulates and transfers a rasterized print job to the MFP 110 b. The network management subsystem 325 comprises software for interfacing the Host 110 b to the workstations 150 through the LAN interface 215 and LAN 160.

The transport layer 330 includes two functional units: an MFP interface transport 331 and a network service transport 335. The MFP interface transport 331 controls the communications interface 205, and thus communications between the Host 110 b and the MFP 110 a. The network service transport 335 comprises software for implementing NetBEUI, TCP/IP, IPX/SPX and other transport protocols which are used in network 100 communications.

FIG. 3 also shows data flow between the functional units. The print application 313 receives print commands and control messages from workstations 150 via the network management subsystem 325 from the network service transport 335. In one embodiment, print commands may be sent to the print application 313 from either or both of a Novell print server and a Microsoft Windows NT print spooler, through the network services transport 335. The print application 313 sends print jobs associated with the print commands to the PDL interpreter 311. Data to be printed is then sent from the PDL interpreter 311 to the printer subsystem 321 via the DSRU 315 and, subsequently, sent to the MFP interface transport 331 for printing by the MFP 110 a. The PDL interpreter 311 is therefore said to be an originator service because it originates print image data for use by downstream services. Likewise, the printer subsystem 321 is said to be a recipient service because it receives print image data from upstream services.

Referring now to FIG. 4, the facsimile send application 411 comprises software responsive to control messages sent by the workstations 150 for controlling how facsimile send jobs originating from the workstations 150 and/or the MFP 110 a are processed. The facsimile send application 411 can also be configured to be responsive to control messages sent by the MFP 110 a for controlling how facsimile send jobs initiated at the MFP 110 a and/or received from workstations 150 are processed. The facsimile send application 411, in response to the control messages, can then act upon and respond differently to other functional units. The facsimile send application 411 is an originator service. Also included in the applications layer 410 is the DSRU 315.

The subsystems layer 420 includes the panel subsystem 428, a facsimile subsystem 421 and the network management subsystem 325 (described above with reference to FIG. 3). The panel subsystem 428 comprises software which interprets operations of the control panel 240 and preferably provide user interfaces for the MFP 110 a. The facsimile subsystem 421 comprises software which converts a fax job into a data compatible for the fax/modem 210. The facsimile subsystem is a recipient service 421.

Three functional units in the transport layer 430 are also provided. These include the MFP interface transport 330, a TAPI transport 431 and the network service transport 335. The TAPI transport 460 preferably comprises a software layer that effectively insulates applications programs from modem and fax/modem hardware considerations using Microsoft's telephony advanced programming interface (TAPI). The TAPI standard 431 defines both a single front end applications programming interface (API) to which applications developers write to access the Windows telephony features, and a single back-end service provider interface (SPI) for Windows to access telephony hardware and telephony services. Thus, through the TAPI transport 431, TAPI-compliant applications can control the fax/modem 210 on a generic basis.

FIG. 4 also shows how data flows between the functional units. The facsimile send application 411 receives facsimile send commands from the operator console 240 via the panel subsystem 428 and from workstations 150 via the network management subsystem 325. The MFP interface transport 331 is used by the panel subsystem 428 to access and control the control panel 240. The facsimile send application 411 sends facsimile jobs, associated with the facsimile send commands from the MFP 110 a and the workstations 150, to the facsimile subsystem 421 via the DSRU 315. The image data from the facsimile send application 411 is subsequently sent by the facsimile subsystem 421 to the TAPI transport 432 for faxing on the fax/modem 210. The TAPI transport 431 provides the facsimile subsystem 421 with access to the fax/modem 210, over which the facsimile messages are sent.

Turning now to FIG. 5, the DSRU 315 is shown interposed in a print data pipeline 510 between the PDL interpreter 311 and the printer subsystem 321 and a facsimile send data pipeline 520 between the facsimile send application 411 and the facsimile subsystem 421. Image data from the workstations 150 in the form of print commands is pipelined from the PDL interpreter 311 to the printer subsystem 321. Image data in the form of facsimile send commands from the workstations 150 and/or the MFP 110 a is pipelined from the facsimile send application 411 to the facsimile subsystem 421. The scope of the present invention includes having the DSRU 315 throttle additional pipelines between other originator services and recipient services.

The DSRU 315 comprises software which throttles data transfers between originator services and recipient services, and preferably comprises a shared dynamic linked library (DLL). The DSRU 315 effectively conserves the system resources of the Host 110 b to promote high pipeline throughput.

Preferably, a user may define at least some of the parameters used by the DSRU 315 to throttle the print pipeline 530 and the facsimile send pipeline 540. For example, a user may adjust the throttling of the DSRU 315 by defining a maximum amount of throttling that can be applied during high-throughput data transfers or other taxing operations that would otherwise detrimentally consume significant system resources. The user might adjust the throttling based upon, for example, the total available amount of system resource of the Host 110 b.

In addition, the DSRU 315 preferably can adjust its performance dynamically. One way to achieve this is to have each originator service and recipient service register with the DSRU 315. Then, the DSRU 315 analyzes each new service registering and each old service de-registering and adjusts its configuration accordingly.

FIG. 5 also shows the DSRU interfacing face buffers 515. The face buffers 515 comprise image-data holding memory regions in the memory 250. A “face” is defined herein as all of the image data which will be printed on a single side of one sheet of paper. Thus, one page of a single-sided document to be printed has one face, while one page of a two-sided document has two faces. Data transfers in the pipelines 530, 540 preferably occur in units of faces.

Originator services and recipient services need face buffers of differing types. For example, originator services such as the PDL interpreter 311 and the facsimile send application 411 need face buffers which they can fill with faces for use by the recipient services in their respective pipelines 530, 540. Similarly, recipient services need face buffers which have been filled by the originator service of their respective pipeline. The DSRU 315 responds to requests by the services for face buffers by providing the location in memory 250 of a face buffer of the requested type.

The face buffers 515 are preferably shared with the facsimile receive application (not shown), so that when facsimile messages are received they may be controlled in a manner similar to the control of print jobs.

Referring now to FIG. 6, there is shown a flowchart of the method of the invention. In accordance with the method, system resources of the Host 110 b are efficiently apportioned by the DSRU 315 between a first image data processing process in the Host 110 b (such as the print pipeline 530) and a second image data processing process in the Host 110 b (such as the facsimile send pipeline 540) in the Host 110 b. The first process involves a transfer of image data from a first originator service to a first recipient service, such as from the PDL interpreter 311 to the printer subsystem 321. The second process involves a transfer of image data from a second originator service to a second recipient service, such as from the facsimile send application 411 to the facsimile subsystem 421.

After the method is begun (step 605), the data storage and retrieval unit identifies an available number of face buffers in the Host's memory 250 (step 610). In identifying available face buffers, the DSRU 315 preferably determines a percentage of system resources that are to be used by the Host 110 b for supporting the image data processing processes which pass through the DSRU 315. Based upon this determination, the DSRU 315 then identifies an available number of face buffers to reflect the determined percentage of system resources.

More preferably, the DSRU 315 determines a percentage of system resources that are to be used by each image data processing process. For each image data processing process, the DSRU 315 sets aside a number of face buffers to reflect the determined percentage of system resources that are to be used by the Host 110 b for supporting the image data processing process.

The DSRU 315 is available to receive face buffers requests from any of the services, such as PDL interpreter 311, printer subsystem 321, facsimile send application 411 and facsimile subsystem 421. However, the PDL interpreter 311 and facsimile send application 411 will request empty face buffers from the DSRU 315, and the printer subsystem 321 and facsimile subsystem 421 will request filled face buffers from the DSRU 315. Because the services operate independently, their requests to the DSRU 315 are made in an unpredictable order.

After one of the services requests a face buffer, whether empty or filled (step 615), the DSRU identifies an available number of face buffers which meet the criteria (step 620). For a request from the PDL interpreter 311 or the facsimile send application 411, the DSRU 315 simply identifies empty face buffers. For a request from the printer subsystem 321, the DSRU 315 identifies face buffers which have been filled by the PDL interpreter 311. Similarly, for a request from the facsimile subsystem 421, the DSRU 315 identifies face buffers which have been filled by the facsimile send application 411.

From a more general perspective, when an originator service requests an empty face buffer, the DSRU 315 identifies any empty face buffer. When a recipient service requests a filled face buffer, the DSRU 315 identifies only face buffers filled by the corresponding originator service. This preserves the integrity of the image data processing processes.

Proceeding to step 625, if at least one face buffer of the requested type is available, then the DSRU 315 returns a location of the one available face buffer to the requesting service (step 630). If the requesting service is an originator service, then the originator service fills the face buffer. If the requesting service is a recipient service, then the recipient service empties the face buffer.

If the DSRU 315 is unable to identify any face buffers of the requested type, then the DSRU delays until at least one face buffer of the requested type becomes available (step 635) and then the DSRU 315 returns a location of the face buffer to the requesting service (step 630). This delay may take any of a number of forms. The delay is preferably event driven, such that a release of a face buffer triggers the completion of a face request. Alternatively, the DSRU 315 may set a timer and await its expiration before rechecking for available face buffers of the requested type. The DSRU 315 might also place the request in a queue, service one or more other requests, and then return to requests in the queue. For requests for empty face buffers, the DSRU could simply operate on a first come, first served basis.

Preferably, the DSRU 315 includes a prioritization mechanism, and this prioritization mechanism is incorporated into the queue. The prioritization scheme preferably gives highest priority to walk-up users of the MFP 110 a, then priority to print jobs, and lowest priority to fax jobs. The prioritization of a particular job is further increased with its elapsed delay tp prevent starvation. Also, recipient processes preferably have higher priority over origination processes.

With the request satisfied, the method continues at step 610 as discussed above to achieve dynamic allocation of face buffers. Alternatively, where the DSRU 315 will work with a fixed number of face buffers, the method would continue at step 615.

FIGS. 7 is timing diagram illustrating the method of FIG. 6 as applied to an examples where only a single face buffer remains available to the DSRU 315. The timing diagram of FIG. 7 has five phases.

In the first phase 710, the PDL interpreter 311 requests an empty face buffer from the DSRU 315 in connection with a print job that has been initiated, and DSRU 315 provides the location of the single available empty face buffer to the PDL interpreter 311.

In the second phase 720, the printer subsystem 321 requests a filled face buffer from the DSRU 315, the request corresponding to the print job. Since the DSRU 315 does not have any available filled face buffers for the printer subsystem 321 , the request is delayed.

In the third phase 730, the facsimile send application 411 requests an empty face buffer from the DSRU 315, and the request is delayed since no empty face buffers are available.

In the fourth phase 740, the PDL interpreter 311 fills the face buffer and returns this fact to the DSRU 315 and, subsequently, the DSRU 315 forwards the location of the filled face buffer to the printer subsystem 321, thus vitiating the earlier delay that was sent to the printer subsystem 321 in the second phase 720.

In the fifth phase 750, the printer subsystem 321 processes the face of image data for forwarding to the MFP 110 a, and provides an indication to the DSRU 315 that the face buffer can now be considered as empty or available. Upon receipt of the indication from the printer subsystem 321, shown as a returned face buffer in FIG. 7, the DSRU 315 sends the location of the now-available face buffer to the facsimile send application 411 in a fifth phase 750, to satisfy the request by the facsimile send application 411 in the third phase 730.

FIG. 8 is another timing diagram illustrating the method of FIG. 6 as applied to another example where only a single face buffer remains available to the DSRU 315. The timing diagram of FIG. 8 illustrates a similar scenario where the facsimile send application 411 is the first to request a last-available empty face buffer from the DSRU 315. The timing diagram of FIG. 8 has five phases.

In the first phase 810, the DSRU 315 receives a request from the facsimile send application 411 for an empty face buffer and the DSRU fills the request.

In the second phase, the facsimile subsystem 421 sends a request to the DSRU 315 for a filled face buffer. The facsimile send application 411 has not yet filled the empty face buffer and in this example there are no other face buffers which the facsimile send application has filled. Therefore, the DSRU 315 replies to the facsimile subsystem 421 with a delay message.

In the third phase, the PDL interpreter 311 requests an empty face buffer from the DSRU 315. Since the facsimile send application 411 received the last empty face buffer, the DSRU 315 issues a delay message to the PDL interpreter 311.

In the fourth phase 840, the facsimile send application 411 completes the transfer of a face of image data into the face buffer and returns this to the DSRU 315. Because the facsimile subsystem 421 was waiting for a face buffer filled by the facsimile send application 411, the DSRU 315 provides the location of the filled face buffer to the facsimile subsystem 421.

In the fifth phase, the facsimile subsystem 421 processes the face of image data in the face buffer and notifies the DSRU 315 that the face buffer is empty. The DSRU 315 then forwards the location of the empty face buffer to the PDL interpreter 311 in response to the earlier request of the PDL interpreter 311.

In the examples of FIGS. 7 and 8, face buffers are supplied to the face buffer requesters based only on an availability, first-come first-served basis. A number of other assignment schemes for distributing the resources available to the DSRU 315 for servicing the print and facsimile send pipelines 530, 540 are within the scope of the invention. Various prioritizing schemes may be programmed or selected in accordance with the present invention. Additionally, the various prioritizing schemes for distributing face buffers among the pipelines may be dynamically selected in accordance with predefined criteria.

For example, a facsimile command containing faces of image data to be printed in low resolution form may provide a signal to the DSRU 315 to provide less throttling to the facsimile send pipeline, since the actual pages may be processed (faxed) by the fax/modem 210 at a higher rate.

In accordance with one aspect of the present invention, the throttling of the print pipeline and the facsimile send pipeline does not affect the ultimate output of hard copies printed by the MFP 110 a and faxed by the fax/modem 210. Other prioritizing and resource allocation schemes may be implemented by the DSRU 315 to ensure that the final print and facsimile send outputs are not substantially delayed by the throttling of the DSRU 315.

In accordance with another alternative embodiment of the present invention, a user may input a number of resource-conserving modes before or during the processing of print and/or facsimile image data. A user wishing to place a high priority on a particular print job, for example, may transmit information with a print command from a workstation 150 to prioritize the particular print job over other facsimile and/or print jobs. Priority would be provided by assigning available face buffers to the particular print job even when, for example, a facsimile job was requested first.

Although exemplary embodiments of the present invention have been shown and described, it will be apparent to those having ordinary skill in the art that a number of changes, modifications, or alterations to the invention as described herein may be made, none of which depart from the spirit of the present invention. All such changes, modifications and alterations should therefore be seen as within the scope of the present invention. 

It is claimed:
 1. A method of apportioning system resources of a host between a first image data processing process and a second image data processing process in the host by a data storage and retrieval unit in the host, the host comprising a processor and a memory, the first process involving a transfer of image data from a first service to a second service, and the second process involving a transfer of image data from a third service to a fourth service, the method comprising the steps of: (a) the data storage and retrieval unit identifying an available number of face buffers in the memory, the face buffers each comprising a working region of the memory for temporarily storing a face of image data; (b) the data storage and retrieval unit receiving a plurality of requests for face buffers in an unpredictable order, the requests comprising: (i) the first service requesting a empty face buffer from the data storage and retrieval unit; (ii) the second service requesting a filled face buffer from the data storage and retrieval unit; (iii) the third service requesting a empty face buffer from the data storage and retrieval unit; (iv) the fourth service requesting a filled face buffer from the data storage and retrieval unit; (c) if one of the first service or the third service requests an empty face buffer, then: (i) the data storage and retrieval unit identifying an available number of empty face buffers; (ii) if at least one empty face buffer is available, then the data retrieval and storage unit returning a first location of one available empty face buffer to the requesting service for the requesting service to fill; (iii) if no empty face buffers are available, then the data retrieval and storage unit delaying until at least one empty face buffer becomes available and then the data retrieval and storage unit returning a second location of one available empty face buffer to the requesting service for the requesting service to fill; (d) if the second service requests a filled face buffer, then: (i) the data storage and retrieval unit determining whether there are any face buffers filled by the first service; (ii) if at least one face buffer filled by the first service is available, then returning a third location of one face buffer filled by the first service to the second service for the second service to use; (iii) if no face buffers filled by the first service are available, then the data retrieval and storage unit delaying until at least one face buffer filled by the first service becomes available and then returning a fourth location of one face buffer filled by the first service to the second service for the second service to use; (e) if the fourth service requests a filled face buffer, then: (i) the data storage and retrieval unit determining whether there are any face buffers filled by the third service; (ii) if at least one face buffer filled by the third service is available, then returning a fifth location of one face buffer filled by the third service to the fourth service for the fourth service to use; (iii) if no face buffers filled by the third service are available, then the data retrieval and storage unit delaying until at least one face buffer filled by the third service becomes available and then returning a sixth location of one face buffer filled by the third service to the fourth service for the fourth service to use.
 2. The method of apportioning system resources of a host between a first image data processing process and a second image data processing process in the host by a data storage and retrieval unit in the host as set forth in claim 1, wherein the step of identifying an available number of face buffers comprises: (a) the data storage and retrieval unit determining a percentage of system resources that are to be used by the host for supporting the first image data processing process and the second image data processing process; and (b) the data storage and retrieval unit identifying an available number of face buffers to reflect the determined percentage of system resources that are to be used by the host for supporting the first image data processing process and the second image data processing process.
 3. The method of apportioning system resources of a host between a first image data processing process and a second image data processing process in the host by a data storage and retrieval unit in the host as set forth in claim 1 further comprising the steps of: a first general purpose computer workstation transferring image data to the host to be processed in the first image data processing process and the second image data processing process; a second general purpose computer workstation transferring image data to the host to be processed in the first image data processing process and the second image data processing process.
 4. The method of apportioning system resources of a host between a first image data processing process and a second image data processing process in the host by a data storage and retrieval unit in the host as set forth in claim 1 wherein: the host includes a fax/modem and further is coupled to a multifunction peripheral through an interconnect; and the third service comprises a facsimile send application and the fourth process comprises a facsimile subsystem.
 5. The method of apportioning system resources of a host between a first image data processing process and a second image data processing process in the host by a data storage and retrieval unit in the host as set forth in claim 1 wherein: the host is coupled to a printer; and the first service comprises a PDL interpreter and the second service comprises a printer subsystem.
 6. The method of apportioning system resources of a host between a first image data processing process and a second image data processing process in the host by a data storage and retrieval unit in the host as set forth in claim 1, wherein steps (b) through (d) are performed non-sequentially.
 7. The method of apportioning system resources of a host between a first image data processing process and a second image data processing process in the host by a data storage and retrieval unit in the host as set forth in claim 1 wherein the data storage and retrieval unit returning locations of the available empty face buffers on a first come, first served basis.
 8. The method of apportioning system resources of a host between a first image data processing process and a second image data processing process in the host by a data storage and retrieval unit in the host as set forth in claim 1, wherein the step of identifying an available number of face buffers comprises dynamically identifying an available number of face buffers based upon a percentage of system resources that are presently available at the time of the identification.
 9. The method of apportioning system resources of a host between a first image data processing process and a second image data processing process in the host by a data storage and retrieval unit in the host as set forth in claim 1, wherein the step of identifying an available number of face buffers comprises: (a) determining a first percentage of system resources that are to be used by the host for supporting the first image data processing process; (b) determining a second percentage of system resources that are to be used by the host for supporting the second image data processing process; (c) selecting a first available number of face buffers to reflect the determined percentage of system resources that are to be used by the host for supporting the first image data processing process; and (d) selecting a second available number of face buffers to reflect the determined percentage of system resources that are to be used by the host for supporting the second image data processing process.
 10. The method of apportioning system resources of a host between a first image data processing process and a second image data processing process in the host by a data storage and retrieval unit in the host as set forth in claim 1 comprising, after the second service uses the one face buffer, (a) the second service notifies the data storage and retrieval unit that the one face buffer is empty; (b) the data storage and retrieval unit returning the location of the one face buffer to the first service if there is a pending request for an empty buffer.
 11. A method of apportioning system resources of a host to a first image data processing process in the host by a data storage and retrieval unit in the host, the host comprising a processor and a memory, the first process involving a transfer of image data from a first originator service to a first recipient service, the method comprising the steps of: (a) the data storage and retrieval unit identifying an available number of face buffers in the host's memory, wherein a face buffer comprises a working region of memory for temporarily storing a face of image data; (b) the data storage and retrieval unit receiving requests for face buffer from the services, wherein the first originator service requests empty face buffers and the first recipient service requests filled face buffers; (c) the data storage and retrieval unit identifying an available number of face buffers as requested; (d) if at least one face buffer of the requested type is available, then the data storage and retrieval unit returning a location of the one available face buffer to the requesting service; (i) if the requesting service is the first originator service, then the first originator service filling the face buffer; (ii) if the requesting service is the first recipient service, then the first recipient service emptying the face buffer; (e) if the data storage and retrieval unit is unable to identify any face buffers of the requested type, then the data storage and retrieval unit delaying until at least one face buffer of the requested type becomes available, and then the data storage and retrieval unit returning a location of the face buffer to the requesting service.
 12. The method of apportioning system resources of a host to a first image data processing process in the host by a data storage and retrieval unit in the host as set forth in claim 11 further comprising apportioning system resources of the host to a second image data processing process in the host, the second process involving a transfer of image data from a second originator service to a second recipient service.
 13. The method of apportioning system resources of a host to a first image data processing process in the host by a data storage and retrieval unit in the host as set forth in claim 12, wherein (a) when the first originator service or second recipient service requests an empty face buffer, the data storage and retrieval unit identifying any empty face buffer; and (b) when a recipient service requests a filled face buffer, the data storage and retrieval unit identifying only face buffers filled by the corresponding originator service.
 14. The method of apportioning system resources of a host to a first image data processing process in the host by a data storage and retrieval unit in the host as set forth in claim 12, wherein the step of identifying available face buffers comprises: (a) the data storage and retrieval unit determining a percentage of system resources that are to be used by the host for supporting each image data processing process which passes through the data storage and retrieval unit; and (b) the data storage and retrieval unit identifying an available number of face buffers to reflect the determined percentage of system resources.
 15. The method of apportioning system resources of a host to a first image data processing process in the host by a data storage and retrieval unit in the host as set forth in claim 12, wherein the delay comprises the data storage and retrieval unit setting a timer, awaiting expiration of the timer and rechecking for available face buffers of the requested type.
 16. The method of apportioning system resources of a host to a first image data processing process in the host by a data storage and retrieval unit in the host as set forth in claim 12, wherein the delay comprises the data storage and retrieval unit placing the request in a queue, the data storage and retrieval unit servicing one or more other requests, and then the data storage and retrieval unit returning to service requests in the queue.
 17. The method of apportioning system resources of a host to a first image data processing process in the host by a data storage and retrieval unit in the host as set forth in claim 16, the data storage and retrieval unit servicing the queue in accordance with prioritization rules.
 18. The method of apportioning system resources of a host between a first image data processing process and a second image data processing process in the host by a data storage and retrieval unit in the host as set forth in claim 11, wherein the step of identifying an available number of face buffers comprises dynamically identifying an available number of face buffers based upon a percentage of system resources that are presently available at the time of the identification.
 19. The method of apportioning system resources of a host to a first image data processing process in the host by a data storage and retrieval unit in the host as set forth in claim 11, wherein the step of identifying available face buffers comprises: (a) the data storage and retrieval unit determining a percentage of system resources that are to be used by the host for supporting the first image data processing process which pass through the data storage and retrieval unit; and (b) the data storage and retrieval unit identifying an available number of face buffers to reflect the determined percentage of system resources.
 20. The method of apportioning system resources of a host to a first image data processing process in the host by a data storage and retrieval unit in the host as set forth in claim 11, wherein the services operate independently and request face buffers from the data storage and retrieval unit in an unpredictable order.
 21. The method of apportioning system resources of a host to a first image data processing process in the host by a data storage and retrieval unit in the host as set forth in claim 11 wherein the method comprises a continuous loop.
 22. The method of apportioning system resources of a host to a first image data processing process in the host by a data storage and retrieval unit in the host as set forth in claim 21 wherein the step of the data storage and retrieval unit identifying an available number of face buffers is only performed once. 